Study of the conformational change of amylose induced by

Jul 22, 1992 - Maebashi-shi 371, Japan, and The Institute of Physical and. Chemical Research, 2-1 Hirosawa, Wako-shi 351-01, Japan. Received December ...
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Macromolecules 1992,25, 6699-6702

6699

above saturation. The ionic strength of the complex solutions prepared were 0.53 f 0.04and 0.14f 0.01 for AMA and AMB, respectively. Polymer concentrations of the complex solutions were 4.7 and 0.37 wt % for AMA and AMB, respectively. Measurements were carried out 10 min after the complexation. Small-Angle X-ray Scattering Measurements. Smallangle X-ray scattering measurements used a synchrotron radiation X-ray scattering spectrometer for enzymes at the National Laboratory for High Energy Physics, Ttaukuba, Japan. The X-ray beam is monochromatized by using a double-crystal monochromator and focused with a toroidal focusing mirror. Scattering data are recorded by using a one-dimensionalpoeitionsensitive proportional counter with a probe 20 cm in effective length. We used 1.49-A radiation and a sample-to-detector distance of 65 cm. Slit corrections were not carried out because quasi-point-type optics were used. The details of the optics and instruments are given Samples were contained in a quartz cell with 1-mm path length, and the temperature of the sample holder was maintained at 15.0 f 0.1 "C by circulating water. Exposure time was 900 s for each sample. The electron current in the storage ring was 140-260 mA.

S t u d y of the Conformational Change of Amylose Induced by Complexation with Iodine Using S y n c h r o t r o n X-ray Small-Angle

Scattering Toshihiro Hirai>t Mitsuhiro Hirai,' Sadao Hayashi: and Tatsuo Ueki* Faculty of Textile Science and Technology, Shinshu University, 3-15-1 Tokida, Ueda-shi 386, Japan, Faculty of General Studies, Gunnma University, 4-2 Aramaki-cho, Maebashi-shi 371, Japan, and The Institute of Physical and Chemical Research, 2-1 Hirosawa, Wako-shi 351-01, Japan Received December 30, 1991 Revised Manuscript Received July 22, 1992

Introduction Amylose has been known to form a blue complex with iodine in the presence of iodide in aqueous solution.' The crystal structure of the amylose-iodine complex reveals a clathrate, in which the polyiodine is included in the helical cavity of the a m y l o ~ e . The ~ ~ ~structure of the iodine Scattering Data Analysis complex of cyclodextrin was also investigated in detail as a model of the iodine complex of a m y l ~ s e . ~ - ~ The calibrated scattering intensity I ( q ) from particles However, the structure of the complex in aqueous is obtained from solution is still ambiguous in spite of many i n v e s t i g a t i o n ~ . ~ *The ~ ? ~fundamental -~~ structure of the complex in aqueous solution is believed to be basically the %ol' sol %OlV' solv same as in the crystal or solid form with the polyiodine in the channel of the helix. The structure change on where q = 4dsin W A , 28, A, Isoi(q),I s 0 ~ d qCsolv, ) , CsOlv, T-1, complexation has also been investigated from various and TmlV represent the scattering angle, wavelength, the points of v i e ~ . ~ ~ ~ - ~ ~ ~ , ~ In ~ ~this ~ ~ paper, ~ ~ 6 - we 2 8tried , 3 0 , 9 ~ scattering intensities of the solution and pure solvent, the to study it by using small-angle X-ray scattering of the incident X-ray beam intensities for the solution and for synchrotron orbital radiation (SORI. This technique the solvent monitored using the ion chamber just in front allows us to follow the structure change in the solution of the sample cell, and the X-ray beam transmissions accompanying complexation. The results were obtained through the samples, respectively. The suffixes, sol and after eliminating the strong background due to the solv, refer to the solution and the solvent, respectively. scattering by heavy atoms, illustrating the effectiveness The T values are estimated by use of the X-ray mass of the strong X-ray beam of SOR. absorption coefficients of the elements in the samples. Experimental Section The I ( q ) values were corrected first by analysis of the beginning of the scattering curve by using the Guinier Materials and Complexation of Amylose with Iodine. Amyloses were purchased from Nakarai Chemicals Co., with equation molecular weighta of 2900 and 16 OOO, which were designated by AMA and AMB, respectively. Other chemicalsused were reagent I ( q ) = I(0) exp(-q2R;/3) (2) grade and were used without further purification. Iodine where I(0)designates the zero-angle scattering intensity complexes of the amyloses were prepared by mixing the amylose and R, is the radius of gyration.36 aqueous solution of iodine and iodide. In order to obtain sufficient scattering intensity and a shorter irradiation time, the polymer The zero-angle scattering intensity, I(O),is proportional concentration was kept as high as possible, and the polymers to the square of the total particle scattering amplitude were solubilized in a 1N KOH aqueous solution. The irradiation and can be expressed in the form time should be short to avoid gelation of the polymer solution. The concentrations of the stock polymer solutions were 10.0wt % for AMA and 3.00 wt % for AMB, respectively. In the case of AMB, because of the high viscosity of the stock solution, we had to reduce the concentration to the low value given above. Right before the complexation the polymer stock solution was neutralized to pH 7.0with acetic acid and diluted if needed. The concentrations of the neutralized polymer solutions were 9.5 and 0.74 wt % for AMA and AMB, respectively. The complex solutions, with [I2]/[Kll = 0.10, were prepared by addition of an aliquot of a stock solution containing 0.2 M KI and 0.02 M 12. Iodine binding affinities of AMA and AMB were estimated as 1 mg of Id100 mg of polymer and 20 mg of Iz/100 ~ ~ ~ mg of polymer, respectively, according to Banks et a l . The iodine concentration added was varied from below saturation to

* To whom correspondence should be addressed. t Shinshu University. t f

Gunnma University. The Institute of Physical and Chemical Research. 0024-929719212225-6699$03.00/0

where p ( r ) , ps, p ( r ) , and p are the scattering density distribution of the particle, the average scattering density of the solvent, and the excess scattering density distribution of the particle with respect to pa and ita average scattering density (so-called "contrast"), respectively.3' The radius of gyration, R,, is defined as (4) To determine R, values and I(0) intensities, we used the least-squares method for the Guinier plot, In I ( q ) vs q 2 in the q range 0.020-0.035 A-l. The second analysis for the total scattering curve is carried out by calculating the distance distribution func-

0 1992 American Chemical Society

Macromolecules, Vol. 25, No. 24, 1992

6700 Notes

,

Figure 1. Observed small-angle X-ray scattering curves of amylose-iodine complexes at a series of iodine concentrations. Molecular weight = 2900 (abbreviated as AMA). lOs[I~l(mol/L) = (a) 0, (b) 2.0, (c)6.0. [amylose] = 0.29 (unit mol)/L, [I2]/KI] = 1/10 at 15 O C . tion, p ( r ) . The functionp(r) is given by Fourier inversion of the scattering intensity I ( q ) as p ( r ) = 3JmrqI(q)sin (rq)dq

(5)

I

-2

-1

Log q (A-1) Figure 2. Observed small-angle X-ray scattering curves of amylose-iodine complexes at a series of iodine concentrations. Molecular weight = 16 OOO (abbreviated as Am).104[I~](mol/ L) = (a) 0, (b) 6.0, (c) 20.0. [amylose] = 0.023 (unit mol)/L, [I2]/[KI] = 1/10 at 15 "C.

It depends both on the particle geometry, expressing the set of distances joining the volume elements within a particle, and on a particle inner inhomogeneity distribution. In calculating the functionm p ( r ) ,the extrapolation method using the Guinier plot was applied for the smallangle data sets and the modified intensity as ~ ( q=) ~ ( qexp(-kq2) )

(6)

(k,an artificial damping factor, was used so as to remove the Fourier truncation effect.) The maximum diameter, D,, of the particle can be estimated from the&) function satisfying the condition p ( r ) = 0 for r > Dmm. Results and Discussion The log 1(q) vs log g plots in Figures 1 and 2 show the scattering curves of the iodine complexes, AMA and AMB, as a function of iodine concentrations. In Figures 1-4, (a)-(c) correspond to the scattering curve of native solution with 0 mol/L [I23, an iodine complex solution with a medium concentration of 12,and an iodine complex solution with the highest concentration of 12, respectively. By comparison of the profiles of these plots, it can be seen that in the case of AMA the scattering curve is changed drastically, suggesting a structural change of the AMA molecule. In the case of AMB there is no major change in the scattering curve, so the structural change of the AMB molecule was assumed to be small. According to the Guinier plots, as shown in Figures 3 and 4, the R value of AMA increased remarkably from 20.5 to 41.1 whereas that of AMB decreased slightly from 58.5 to 55.1 A. Using eq 3 the ratio of the volume change on complexation with iodine can be estimated by comparison of zero-angle scattering intensities. At a constant molar concentration c of AMA the zero-angle

k,

1

I

I

6.25

12.50

104 q2

I I 18.75

(A-2)

Figure 3. Guinier plots for the scattering curves in Figure 1. The marks used correspond to those in Figure 1. The straight lines obtained by the least-squares method for Guinier plota in the q range 0.034.04 A-1 are used to determine R, and I(0) intensities. scattering intensity of oligomer made up of n AMA molecules, l o ~ ( 0 is ) , given by

I ~ ~ (=o :(njW2 ) = nc(jW2 = n1(0)

(7)

where we can neglect the change of the contrast accompanying the amylose-iodine complexation. The difference of the average scattering density between the complex and its solvent and that for the native solution have approximately the same value because the increase in the average scattering density for solvent, (p[l N KOH + 0.006

Macromolecules, Vol. 25, No. 24, 1992 . I

I

Notes 6701 I

2

h

.-C v

.I-

)

'

3

F m .-z o

I 6.25

e

m

2

W A

v L

P

12.50

18.75

1

104q2 (A-2) Figure 4. Guinier plots for the scattering curves in Figure 2. The marks used correspond to those in Figure 2. The straight lines obtained by the least-squares method for Guinier plots in the q range 0.034.04 A-1 are used to determine R, and I(0) intensities.

M I2 + 0.06 M KII - p[1 N KOHl)/p[l N KOHI, is 8.5 X

and that for solute, (p[AMAl - p[I-AMAl)/p[AMAl, is 7.2 X lO-9according to iodine binding affinities of AMA 1 mg of Id100 mg of polymer. The contribution to the variation in zero-angle scattering intensity by the change of the contrast is then below 1%, smaller than the experimental errors. Therefore the ratio of the volume change is proportional to the ratio, nI,dO)/I(O),and n = 9 was obtained by our experiments. The distance distribution functions calculated by using eq 5 are shown in Figure 5a,b for AMA and AMB. As seen from Figure 5a, in the case of AMA, the maximum diameter Dm, which corresponds to the length of the intraparticle vector, increased from 85 to 158 A, accompanying the shift of the center of the p ( r ) function to longer distances. The insert, Figure 5c, shows the calculated p ( r ) functions of the model structures for AMA at [I21 = 0 and 0.6 X M. The model for AMA a t 1121 = 0 M is a cylinder with radius 14.6 A and height 61.4 A, and that for for AMA a t [I21 = 0.6 X M is an ellipsoid of rotation with semiaxes 33.2 and 79.0 A. The parameters of those models are adopted so that the R, values and the shapes of the p ( r ) functions coincide with those obtained from the scattering data. The ratio of volume of these two models is 8.9/1, which in the range of experimental error agrees well with experiments, n = 9. This suggests that for AMA the complexation with iodine induces an aggregation of several complexes to an anisotropic structure. In the case of AMB, as shown in Figure 5b, the circumstances are quite different. The slight decrease of the maximum diameter Dm, from 181 to 173 A was not accompanied by a change of the shape of thep(r) functions, suggesting aggregation. The results described above are summarized in Table I. It may be concluded that the AMB structure changes by the addition of iodine from an extended helix to a more tightly wound form, as inferred previously.17~18,29,34 However, AMA, which aggregates somewhat even in the absence of iodine, aggregates further on addition of iodine to an ellipsoidal structure by stacking the AMA molecules, as in cyclodextrin-iodine c0mplexes.~~6 Acknowledgment. We are grateful to Professor T. Matsushita and Dr. Y.Amemiya of the Photon Factory at the National Laboratory for High Energy Physics for the initial setting of the optics and CAMAC data aquisition

0

50

150

100

r

200

ch

Figure 5. Distance distribution functions,p ( r ) ,of AMA-iodine complexes (a) and AMB-iodine complexes (b) as a function of [I21 concentration (mol/L): full line, thin line, and broken line refer to [I21 = 0, [I21 = 0.2 X and 1121 = 0.6 X respectively, and 1121 = in the case of AMA and to [I21 = 0, [I21 = 0.6 X 0.2 X respectively, in the case of AMB. Thesep(r)functions are calculated with the scattering curves obtained by using the extrapolation method and the artificial damping factor. The insert (c) shows the p ( r ) function of the model structures for AMA-iodine complexes corresponding to [I21 = 0 mol/L (thin line) and [I23 = 0.6 X mol/L (broken line). The parameters of these models are given in the text. Table I Some Characteristic Parameters of Amylose Samples at Different Iodine Concentrations concn (mol/L)

peak position of

[I21

RE(& Z*(O)" D , (A) AMA, 0.29 (unit mol)/L

p ( r ) (A)

1 9.4 8.9

20 37 44

* *

0 0.2 X

20.5 0.6 38.8 0.8 41.1 & 0.9

0.6 X

85 157 158

AMB, 0.023 (unit mol)/L 0

58.8 & 1.2 57.1 f 1.2 55.1 1.2

0.6 X 0.2 X

1 1.1 1.1

181 177 173

62

66 69

The zero-angle scattering intensity Z*(O) is normalized by Z(0)

at [I21 = 0.

system. This work was performed under the approval of the Photon Factory Programme Advisory Committee (Proposal No. 87-149). References and Notes (1) (2)

Banks,W.,Greenwood,C. T.,Eds. Starchandits Components; The University Press; Edinburgh, 1975. (a) Rundle, R. E.; Baldwin, R. R. J. Am. Chem. SOC.1943,65, 554. (b) Rundle, R. E.; Edwards, F. C. J. Am. Chem. SOC. 1943,65, 2200. (c) Rundle, R. E.; French, D. J. Am. Chem. SOC.1943,65,558. (d) Rundle,R. E.; French, D. J. Am. Chem. SOC.1943,65,1707. (e) Rundle, R. E.; Daasch, L.; French, D. J. Am. Chem. SOC.1944,66,130. (0Rundle, R. E.; Foster, J. F.;Baldwin, R. R. J.Am. Chem. SOC.1944,66,2116. (g) Rundle, R. E. J. Am. Chem. SOC.1947,69, 1769.

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6702 Notes

Macromolecules, Vol. 25,No.24, 1992

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2710.